cosmic microwave background and foregrounds
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Transcript cosmic microwave background and foregrounds
Cosmic Microwave
Background
Carlo Baccigalupi, SISSA
CMB lectures at TRR33, see the complete program at
darkuniverse.uni-hd.de/view/Main/WinterSchoolLecture5
These lectures are available in pdf format at
people.sissa.it/~bacci/work/lectures
CMB and foregrounds
Outline
Foreground
fundamentals
Galactic synchrotron
Galactic free-free
Galactic dust
The other galaxies and clusters
Contamination to the CMB
Foreground fundamentals: the Galaxy,
the other galaxies, and their clusters
Foreground fundamentals:
differences with respect to the CMB
Together with instrumental systematics, foregrounds are the ultimate
limitation of CMB observations
Unlike CMB, the foreground knowledge is mainly empirical, we know
the main physical processes activating them, but their emission is
calibrated mainly through observations
Unlike CMB, the Galactic emission is strongly inhomogeneous,
concentrated on the Galactic plane
Unlike CMB, the foregrounds do not possess a black body
frequency spectrum
Unlike CMB, the foregrounds do possess a space varying frequency
dependence
Unlike CMB, the diffuse foreground emission is markedly nonGaussian
Unilike CMB, the emission from extra-Galactic object is point-like
Foreground fundamentals
Bennett et al. 2003, Page et al. 2007
Milky way
In microwaves, the main emission
does not come from stars, but
from the diffuse gas, either
primordial and unprocessed, or
ejected
from
stars
through
explosions
The diffuse gas is composed by
free electrons, ions, a variety of
large molecules, also known as
grains, such as silicates, …
The galaxy is an hot system, 20 K
or so, not isolated because heated
back by starlight
The galaxy possesses a magnetic
field of order 10-10 Tesla, with a
large scale component orthogonal
to the plane and elongated along
arms, and a largely unknown
small scale component
Foregrounds coming from
the radio band: Galactic synchrotron
What it is: free electrons
spiraling around the lines of
the Galactic magnetic field
In frequency, it behaves as a
decaying power law, because
the electron number is a
decreasing power law of their
energy, N(E)∝E -|p|
Existing information on all sky,
in total intensity, taken in the
radio band (Haslam et al.
1986, Reich et al. 1998) and in
microwaves
by
WMAP
(Bennett et al. 2003)
Foregrounds coming from
the radio band: Galactic synchrotron
The Galactic synchrotron is
strongly polarized, the polarized
intensity has been found to be a
few ten percent of the total one
The frequency scaling is close to
the one of total intensity
All sky observations in the radio
band exist (La Porta et al. 2006),
but are affected by masking
effects like the Faraday rotation
leading to depolarization
The main observations in the
microwave bands are from WMAP
(Kogut et al. 2007, Page et al.
2007), at 22 GHz where it is
mostly dominating over CMB
Foregrounds coming from
the radio band: Galactic free-free
What it is: Bremstraahlung
radiation from free electrons
hitting ions
It
never
dominates
the
emission: at any frequency,
synchrotron or CMB or other
foregrounds are brighter
It is measured through indirect
Hα emission line
Its
emission
decays
in
frequency, but less fast than
synchrotron, because of the
energy distribution of ions
It is intrinsically unpolarized,
the available observations
from Hα surveys, WMAP data
(Bennett et al. 2003)
Foreground coming from
the infrared band: Galactic dust
What it is: molecules or dust
grains
form
a
thermal
component, temperature of
about 20 K, heated back by
starlight
The emission is described as a
modified (grey) black body,
raising with frequency in the
microwave band
An all sky template from IRAS
at 3000 GHz exists for total
intensity, and the extrapolation
to the microwaves using a grey
body spectrum was found
consistent with the WMAP data
(Bennett et al. 2003)
Foreground coming from
the infrared band: Galactic dust
The grains are magnetized,
and get aligned locally with the
direction of the Galactic
magnetic field, making the
overall emission polarized
The polarized intensity was
found to be about 10% of the
toal one along the Galactic
plane by Archeops (Benoit et
al. 1995) and WMAP (Page et
al. 2006), being probably
higher at higher latitutdes
Other galaxies and their clusters
To imagine the emission from other galaxies, you may
simply think to the one from the Milky Way put at
distance from us, emitting synchrotron emission in the
radio, dust in the infrared
Being point-like, their signal behaves similarly to
instrumental noise
The existing observations indicated a polarized intensity
which is a few percent of the total one in the radio,
comparable in the infrared band
In clusters of galaxies, the central hot gas of electrons
give kicks to the CMB photons, which migrate from low
frequencies to high frequencies, distorting their spectrum
through the Sunyaev Zel’dovich effect
Contamination to the CMB
Masking the Galaxy: total intensity
The sky emission is dominated
by
the
Galaxy
at
all
frequencies
The contamination is always
evaluated after removing its
brightest part, together with the
main known point sources
In total intensity, the removal of
the brightest part of the sky
leaves the sky substantially
dominated by the CMB at
microwave frequencies
The quantification of the
contamination is usually done
by means of the angular power
spectrum of the masked sky
Bennett et al. 2006
Masking the Galaxy: polarization
The sky emission is dominated
by
the
Galaxy
at
all
frequencies
The contamination is always
evaluated after removing its
brightest part, together with the
main known point sources
In polarization, the removal of
the brightest part of the sky
leaves the sky substantially
dominated by the CMB at
microwave frequencies
The quantification of the
contamination is usually done
by means of the angular power
spectrum of the masked sky
Page et al. 2006
Masking the Galaxy: polarization
The sky emission is dominated
by
the
Galaxy
at
all
frequencies
The contamination is always
evaluated after removing its
brightest part, together with the
main known point sources
In polarization, the removal of
the brightest part of the sky
leaves the sky substantially
dominated by the CMB at
microwave frequencies
The quantification of the
contamination is usually done
by means of the angular power
spectrum of the masked sky
Page et al. 2006
CMB contamination: total intensity
Bennett et al. 2003
CMB contamination: polarization
Page et al. 2006
A comparison between WMAP data
and the Planck expectations
Page et al. 2006
Planck reference sky, 2004
Do we have any hope to see B modes?
WMAP has no detection in
large sky areas in polarization
Very naive estimates may be
attempted in those areas,
indicating that the foreground
level might be comparable to
the cosmological B mode at all
frequencies, in all sky regions
We need to rely on multifrequency observations as well
as robust data analysis
techniques which are able to
remove at most the foreground
emission from polarization
CMB data
Page et al. 2006
Are there foreground clean regions
at all in polarization?
WMAP has no detection in
large sky areas in polarization
Very naive estimates may be
attempted in those areas,
indicating that the foreground
level might be comparable to
the cosmological B mode at all
frequencies, in all sky regions
We need to rely on multifrequency observations as well
as robust data analysis
techniques which are able to
remove at most the foreground
emission from polarization
CMB data
Page et al. 2006
Baccigalupi, Hanany et al. 2007
for the EBEx collaboration
Suggested reading
Baccigalupi
2003 for a pre-WMAP review
on foregrounds
Bennett et al. 2003, for the WMAP results
in total intensity
Kogut et al. 2007, Page et al. 2007 for the
WMAP results in polarization